The invention generally relates to systems and methods for providing detection, identification, and precision targeting of specific tissue(s) of interest in a nasal region of a patient for the treatment of a rhinosinusitis condition while minimizing or avoiding collateral damage to surrounding or adjacent non-targeted tissue, such as blood vessels, bone, and non-targeted neural tissue.

A disposable applicator and disposable tray for handling, drying, and separately organizing medical supplies during a medical procedure are provided. The disposable applicator can be used for drying medical supplies. The disposable tray provides two spaced apart recesses for organizing and separating pre-use and post-use medical supplies for preventing cross contamination. The post-use medical supplies, disposable applicator, and the disposable tray can be discarded after the related medical procedure to further prevent the spread of bacteria and viruses.

A coupling tool for coupling together an electronics unit and a base unit of a wearable device for continuous analyte monitoring includes a carrier comprising a receiving feature and a carrier retention device, the carrier retention device configured to retain an electronics unit adjacent the receiving feature. The coupling tool also includes an activator including: a first member at least partially receivable in the receiving feature and a contact member configured to release the electronics unit from the carrier retention device in response to movement of the activator relative to the carrier. The coupling tool is in a locked configuration when the carrier retention device is configured to retain the electronics unit, and the coupling tool is in an unlocked configuration when the carrier retention device is configured to release the electronics unit from the carrier retention device. Other embodiments and methods are also disclosed.

An entirely disposable combined antimicrobial filter and flowmeter device for spirometry applications comprises a tubular body, with an inlet end portion, an outlet end portion, and an intermediate portion of enlarged diameter in the form of a discoidal shell. In the discoidal shell both an antimicrobial filtering membrane and a discoidal net of plastic material generating a pressure differential are arranged, it has an outer peripheral edge fixed to an inner annular lip of one of said bell-shaped portions of the discoidal shell, said annular lip being coaxial to said cylindrical wall. One of the filtering membrane and the pressure differential generating network has an outer peripheral edge fixed to the cylindrical wall of the discoidal shell, while the other of the filtering membrane and the pressure differential generating network has an outer peripheral edge fixed to an inner annular lip of one of the bell-shaped portions defining the discoidal shell.

The present invention relates to an electrode (1) comprising: —at least one reservoir (11) comprising a peripheral wall (111) made of a foam material, wherein said reservoir (11) is filled with a viscous electrolytic paste (12); —at least one plate (13) comprising a conductor material, wherein said plate (13) is in contact with the electrolytic paste (12) and configured to conduct electrical signals to a recording device; —at least one fastener (14); and wherein the at least one reservoir (11) comprises a hole (113) configured to release the electrolytic paste (12) under pressure applied on the electrode (1). The present invention also relates to the use of said electrode (1) and a process for the implementation of an electrode (1).

The present it relates to a sensor applicator assembly for a continuous glucose monitoring system and provides a sensor applicator assembly for a continuous glucose monitoring system, which is manufactured with a sensor module assembled inside an applicator, thereby minimizing additional work by a user for attaching the sensor module to the body and allowing the sensor module to be attached to the body simply by operating the applicator, and thus can be used more conveniently. A battery is built in the sensor module and a separate transmitter is connected to the sensor module so as to receive power supply from the sensor module and. be continuously used semi-permanently, thereby making the assembly economical. The sensor module and the applicator are used as disposables, thereby allowing accurate and safe use and convenient maintenance.

A physiological parameter system has one or more parameter inputs responsive to one or more physiological sensors. The physiological parameter system may also have quality indicators relating to confidence in the parameter inputs. A processor is adapted to combine the parameter inputs, quality indicators and predetermined limits for the parameters inputs and quality indicators so as to generate alarm outputs or control outputs or both.

A wearable sensor and method for providing a wearable sensor are disclosed. In a first aspect, the wearable sensor comprises a first module, wherein the first module comprises a top layer, a printed circuit board (PCB) layer, and a bottom layer. The bottom layer comprises a double adhesive layer that adheres to both the PCB layer and the user. The bottom layer includes at least two openings to house at least two electrodes for monitoring of a user. The wearable sensor further comprises a second module coupled to the first module, wherein the first module is disposable and the second module is reusable. In a second aspect, the method comprises providing the aforementioned wearable sensor.

A re-wearable physiological monitoring device includes a reusable component and a disposable component. The reusable component includes an electronics module and a latching system for latching the reusable component to the disposable component. The disposable component includes an adhesive patch to be adhered to a user's skin, two electrodes to receive electrical signals from the user's skin, a cradle for the reusable component to be latched on, and a battery to power the device. The disposable component may include a “battery disconnect switch” for disconnecting the battery when the reusable component is not latched on; a gasket for isolating each contact between the reusable component and the disposable component in a waterproof enclosure; and a printed contact within the disposable component that is resistant to scratching. A latching system for the device may include two snap fasteners, alignment feet for keeping the reusable component aligned with the disposable component, and an asymmetrical wall to prevent the reusable component from being placed on the disposable component in the wrong orientation. A method of assembling the reusable component by ultrasonic welding is also disclosed.

A system and method to help maintain quality control and reduce cannibalization of accessories and attached probes in a highly sensitive patient monitor, such as a pulse oximetry system. One or more attached components may have information elements designed to designate what quality control mechanisms a patient monitor should look to find on that or another component or designate other components with which the one component may properly work. In a further embodiment, such information elements may also include data indicating the appropriate life of the component.